Adaptive sensitivity in wireless communication

ABSTRACT

A method of accommodating aberrant behavior in wireless devices in a wireless network includes the steps of establishing communication with at least one wireless device, monitoring signals received from the at least one wireless device, determining characteristics of the at least one wireless device based on the monitored signals, comparing the determined characteristics with prescribed characteristics for wireless devices exhibiting aberrant behavior and altering settings to accommodate the at least one wireless device, when the determined characteristics match the prescribed characteristics.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.11/136,376, filed May 25, 2005, entitled, “ADAPTIVE SENSITIVITY INWIRELESS COMMUNICATION,” now U.S. Pat. No. 8,010,120, which claimspriority to U.S. Provisional Patent Application Ser. No. 60/578,296,filed on Jun. 10, 2004 and 60/640,084, filed on Dec. 30, 2004. Thesubject matter of these earlier filed applications are herebyincorporated by reference.

TECHNICAL FIELD

The present invention relates to wireless communication between devices.In particular, the present invention is directed to techniquesapplicable to detect wireless devices that exhibit “aberrant” behavior,with respect to most wireless devices. The techniques disclosed hereinallow for proper, standard communications between devices, even whensome of those devices are operating outside of certain norms.

BACKGROUND

In recent years, there has been rapid growth in mobile computing andother wireless data services, as well as growth in fixed wireless accesstechnologies. These services have the benefit of not requiring wiringbetween nodes to support the networking and potentially allow forcommunication where it could be difficult to provide a wiredinfrastructure. These services can be used to provide high qualitytelephony, high-speed Internet access, multimedia and other broadbandservices.

These wireless devices are tied together through their use of commonnetworking infrastructures. Such wireless networking infrastructuresinclude Institute of Electrical and Electronics Engineers (IEEE)standards 802.11, specifying an over-the-air interface between awireless client and a base station or between two wireless clients. Thestandards allow for transmission between 1-54 Mbps in 2.4 GHz or 5 GHzbands and allow for use frequency hopping spread spectrum (FHSS), directsequence spread spectrum (DSSS), or an orthogonal frequency divisionmultiplexing (OFDM) encoding scheme. In order for the wireless devicesto properly interact, they must all conform to the same standard, oroverlapping standards.

However, even if the wireless devices conform to the establishedstandards, there can be issues that arise. Devices that strictly conformto a standard may operate in a manner that a majority of the otherwireless devices do not. One example occurs with IEEE 802.11 channels,where each channel has a known width. “Well behaved” devices, which arethe vast majority of the devices operating in the world today, send andreceive packets in the center of that channel. Most devices do not watchfor packets out at the edges of the channel. This is a basic tradeoffbetween channel width and general receive sensitivity. This isparticularly an issue with direct conversion radios, a popular methodfor implementing the exchange of data. If the entire width of thechannel is monitored, then general sensitivity would be reduced.

When a wireless device sends and receives packets toward the edge of thechannel, the packets can be lost if only the center is being monitoredand the device may become disassociated from other network elements.While the monitored portions of the channel can be widened, this hasdeficiencies in that if one of these poorly behaved network devices arenot be accessed, there would be a loss in receive sensitivity and somecompatibility issues occur, which can be hard to resolve. Such a problemcould also be dealt with by increasing a tolerable number of droppedpackets, but this would affect decisions wireless devices make duringroaming, resulting in decreased reliability.

Thus, there is a need in the prior art to have wireless devices thathave an adaptable sensitivity to other wireless devices that operateoutside the norms of most of the devices in the wireless network. Suchadaptable sensitivity should allow for a wide variety of the devices tocommunicate without adversely affecting the reliability ofcommunications within the network.

SUMMARY

According to one embodiment, a method of accommodating aberrant behaviorin wireless devices in a wireless network is disclosed. The methodincludes the steps of establishing communication with at least onewireless device, monitoring signals received from the at least onewireless device, determining characteristics of the at least onewireless device based on the monitored signals, comparing the determinedcharacteristics with prescribed characteristics for wireless devicesexhibiting aberrant behavior and altering settings to accommodate the atleast one wireless device, when the determined characteristics match theprescribed characteristics.

Additionally, the steps of monitoring signals, determiningcharacteristics and comparing the determined characteristics may berepeated a predetermined number of times before altering the settings,where the predetermined number may be three. The step of establishingcommunication with at least one wireless device may include establishingcommunication with an access point controlling at least a portion of thewireless network. Also, the steps of monitoring signals, determiningcharacteristics and comparing the determined characteristics may beperformed such that they differentiate when the at least one wirelessdevice is no longer in communication.

Also, the step of monitoring signals received from the at least onewireless device may include determining whether beacon signals arecontinuously being received from the at least one wireless device.Additionally, the step of altering settings may include modifyingphysical layer settings to increase frequency tracking bandwidth. Inaddition, the physical layer settings may be reset after a predeterminedperiod of time. The step of establishing communication may includeassociating with the at least one wireless device according to at leastone of Institute of Electrical and Electronics Engineers (IEEE) 802.11standards. Also, the step of comparing the determined characteristicsmay include comparing the determined characteristics withcharacteristics for wireless devices exhibiting aberrant behavior, wherethat aberrant behavior complies with communications standards for thewireless network.

According to another embodiment, a wireless device in communication in awireless network is disclosed. The device includes establishing meansfor establishing communication with at least one wireless device,monitoring means for monitoring signals received from the at least onewireless device, determining means for determining characteristics ofthe at least one wireless device based on the monitored signals,comparing means for comparing the determined characteristics withprescribed characteristics for wireless devices exhibiting aberrantbehavior and altering means for altering settings to accommodate the atleast one wireless device, when the determined characteristics match theprescribed characteristics.

According to another embodiment, a wireless device in communication in awireless network is disclosed. The device includes at least one antennaand at least one processor, for sending, receiving and processingsignals received and sent through the at least one antenna. The at leastone processor is configured to establish communication with at least onewireless device, monitor signals received from the at least one wirelessdevice, determine characteristics of the at least one wireless devicebased on the monitored signals, compare the determined characteristicswith prescribed characteristics for wireless devices exhibiting aberrantbehavior and alter settings to accommodate the at least one wirelessdevice, when the determined characteristics match the prescribedcharacteristics.

These and other variations of the present invention will be described inor be apparent from the following description of the preferredembodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

For the present invention to be easily understood and readily practiced,the present invention will now be described, for purposes ofillustration and not limitation, in conjunction with the followingfigures:

FIG. 1 illustrates a schematic representation of a wireless network withaccess points and several wireless devices, according to one embodimentof the present invention;

FIG. 2 illustrates a schematic of a channel width of an access channelfor an access point of a wireless network, according to one embodimentof the present invention;

FIG. 3 provides a flowchart of the process identifying and interactingwith non-standard wireless devices, according to one embodiment of thepresent invention; and

FIG. 4 illustrates modules of a wireless device, according to oneembodiment of the present invention.

DETAILED DESCRIPTION

A general wireless network is illustrated in FIG. 1. Two Access Points(APs) 101 and 102 are illustrated, with each AP providing a wirelessaccess area, 110 and 120, respectively. The areas are determined by thepower of the APs and geometries of the antennas 101-a and 102-a of theAPs. Wireless devices, 151 and 152, also have antennas, 151-a and 152-a,and can interact with the APs if the wireless devices are within thewireless access areas. As illustrated in FIG. 1, device 152 would bewithin the coverage area of AP 102 and wireless device 151 is outside ofboth areas. All of the wireless devices, 101, 102, 151 and 152, can haveprocessors, 101-p, 102-p, 151-p and 152-p, for receiving, sending andevaluating signals on the wireless network. Once a device enters awireless access area, it seeks to associate itself with the AP and thereafter send and receive signals to maintain the wireless connection.

As discussed above, IEEE 802.11 channels have known widths. One suchchannel is illustrated in FIG. 2. The edges of the channel areillustrated by the extreme lines 200, with subchannel areas noted byother lines 210, with the channel width 205 spaced about a centerfrequency. Well behaved devices send and receive packets, illustrated inFIG. 2 as 250, in the center of that channel 215 and do not watch forpackets out at the fringe elements of the channel.

Certain devices can send out signals at frequencies that bounce wildlywithin the channel space. Such a signal is illustrated in FIG. 2 as 251.When this occurs, the wireless device cannot reliably see the packetsbeing sent. Some devices have an additional difficulty in that they onlysend certain management frames (beacons) at the 1 IMbit rate, and, assuch, the wireless device cannot maintain connectivity with the AccessPoint (AP).

While the wireless devices have the ability to widen the channelboundaries at which packets are monitored, this has deficiencies in thatif it is not one of these poorly behaved Access Points being accessed,receive sensitivity could be lost and some compatibility issues couldarise which could be hard to resolve.

There are several obvious solutions to such problems, but thosesolutions have their own problems. The wireless device could have a“channel wide” mode, as well as going into a mode where a mass amount ofdropped beacons is accepted to maintain connectivity. Both of these“solutions” have problems. The first solution has already beendiscussed, and can result in reduced sensitivity. The second solutionhas difficulties because it would inflict poor roam decisions for allother access points that the wireless device attempts to work with.

The present invention seeks to “fingerprint” the AP and take certainactions where an AP with known abnormal behavior is identified. In theabove-discussed case, once the aberrant AP is detected, the channelevaluation regions could be widened, and subsequently when the wirelessdevice disassociates from the AP, the width of the channel evaluationcould return to normal.

One embodiment of such a fingerprinting process is illustrated in FIG.3, with the process beginning at step 300. In one embodiment, thewireless device would determine whether beacons were being received froman AP with which the wireless device is associated, in step 310. Ifbeacons are still being received according to a prescribed interval, noaction is taken and the process of monitoring beacon activity continues.If beacons are not continuously being received, the wireless deviceincreases the frequency tracking bandwidth, in step 320. In a particularembodiment, the finding is made only if the wireless device fails toreceive beacons continuously for 7 seconds. Other timings can beselected based on particular system requirements.

Thereafter, the wireless devices determine whether it can receivebeacons using the expanded bandwidth. If the wireless device receives abeacon with this increased bandwidth, it will restore the bandwidth tothe narrow setting, step 330, and check if it can receive packets withthe narrower bandwidth (i.e. go back to step 310). If steps 310 through330 are repeated, for example, three times, step 340, while the wirelessdevice is associated with the AP, step 350, the wireless device willaccept the wide frequency tracking bandwidth, in step 360. This ensuresthat the wide bandwidth will only be selected, if it has been confirmedat least three times, that the wide bandwidth is indeed what is neededto receive beacons and not the wireless device roaming in and out of theservice area of the AP.

Modules of a wireless device, according to one embodiment of the presentinvention, are illustrated in greater detail in FIG. 4. The wirelessdevice 400 again has an antenna 400-a, where that antenna is connectedto various modules. It is noted that in some embodiments, the functionof the separate modules may be performed by a single processor, inhardware and software, as illustrated in FIG. 1. The modules illustratedare an association module 420 that facilitates the association of otherwireless devices with the wireless device 400 and a monitor module 430that monitors signals received through the antenna. Both modules, 420and 430, are in communication with a characterize and compare module410, as well as the antenna 400-a. The latter module is also incommunication with a memory 440 and a settings module, that may be ormay utilize memory. The memory is used for, among other things, storingcharacteristics of wireless devices exhibiting aberrant behavior. Basedon the results of the characterize and compare module, settings providedin the settings module may be altered for a period of time toaccommodate wireless devices exhibiting aberrant behavior.

Additionally, in alternate embodiments, when the wireless device doesnot see any beacons for the prescribed period, it checks to see what thecurrent PHY is. If the current PHY has a particular configuration, itcan modify registers in that PHY core to increase the frequency trackingbandwidth. This ensures that if the AP has a carrier frequency jitter,it can still lock on to the carrier frequency. When the wireless devicedisassociates with the access point, the frequency tracking bandwidth isbrought back to the default value. If the driver is disabled, thewireless management software tells the driver to send a disassociatepacket which goes through the same code path as above. Also, on a resumefrom sleep mode, the wireless device checks to see if the core had awide frequency bandwidth before the device went to sleep and it restoresthe freq tracking bandwidth after waking up.

It is noted that while the issue of signals being sent out from an APoutside of a center channel is discussed, the present invention is notlimited to such a configuration. Rather, the present invention isdirected to assessing abnormal behavior in wireless devices andcorrecting for the abnormality. In the context of the present invention,such abnormal behavior is behavior for which a majority of wirelessdevices for an environment do not exhibit. It is expected that suchabnormal behavior would still be within the specification forcommunication with the network environment, but the present invention isalso applicable to behaviors that are outside of the specification.Generally, the criteria that should be applied in determining whethersuch abnormal behavior should be accommodated involves the weighing ofthe importance of the abnormally functioning device to the overallnetwork environment.

Also, while the examples discussed above address the abnormal behaviorof access points within a wireless environment, the present invention isalso directed to accommodating abnormal behavior of non-access pointwireless devices, such as laptop computers, mobile telephones and otherwireless access devices, which interact with normally behaving APs andwireless devices. Examples of some abnormal behavior by wireless devicesinclude instances where fields in packets are not set or are setimproperly or the use of short slot times where it is not expected.

It is also noted that the present application has been discussed mostlyin terms of access points for IEEE 802.11a/b/g networks, the presentinvention is not limited to such configurations. The present inventionmay be applicable to any wireless networking environment where at leastone of the devices exhibits aberrant behavior that must be accommodated.Besides wireless computing environments operating under the IEEE 802.11standards, the present invention is also applicable to networksoperating under IEEE 802.16, BLUETOOTH™, a short-range radio technology,HomeRF, HiperLAN, WiMax or other configurations. It would also be withinthe scope of the invention to implement the disclosed elements of theinvention in discrete electronic components, thereby taking advantage ofthe functional aspects of the invention. Additionally, the presentinvention can be implemented totally or partially through software.

Although the invention has been described based upon these preferredembodiments, it would be apparent to those of skilled in the art thatcertain modifications, variations, and alternative constructions wouldbe apparent, while remaining within the spirit and scope of theinvention. In order to determine the metes and bounds of the invention,therefore, reference should be made to the appended claims.

1. An apparatus comprising: at least one antenna configured to send andreceive signals; and at least one processor configured to send, receive,and process the signals sent and received by the at least one antenna,wherein the at least one processor is configured to cause the apparatusto: monitor, within a narrow evaluation region, for IEEE 802.11 beaconsignals sent by a wireless device, if the IEEE 802.11 beacon signals arenot received within the narrow evaluation region, monitor the IEEE802.11 beacon signals within a wide evaluation region, if the IEEE802.11 beacon signals are received within the wide evaluation region,reset the monitoring to the narrow evaluation region, and if the IEEE802.11 beacon signals are not received within the narrow evaluationregion after the IEEE 802.11 beacon signals were received within thewide evaluation region at least a predetermined number of times, thepredetermined number being greater than one, accept the wide evaluationregion.
 2. The apparatus of claim 1, wherein the at least one processoris configured to cause the apparatus to widen the narrow evaluationregion to the wide evaluation region based on an absence of the IEEE802.11 beacon signals.
 3. The apparatus of claim 1, wherein the at leastone processor is further configured to cause the apparatus to establishcommunication with the wireless device.
 4. The apparatus of claim 1,wherein the at least one processor is configured to cause the apparatusto reset the monitoring to the narrow evaluation region based onreceiving an IEEE 802.11 beacon signal.
 5. The apparatus of claim 1,wherein the at least one processor is configured to cause the apparatusto reset the monitoring to the narrow evaluation region after apredetermined period of time.
 6. The apparatus of claim 1, wherein thenarrow evaluation region has a width of a subchannel of an IEEE 802.11channel.
 7. An apparatus comprising: at least one antenna configured tosend and receive signals; and at least one processor configured to send,receive, and process the signals sent and received by the at least oneantenna, wherein the at least one processor is configured to cause theapparatus to: monitor, within a narrow evaluation region including asingle channel, for IEEE 802.11 beacon signals sent by a wirelessdevice, if the IEEE 802.11 beacon signals are not received within thenarrow evaluation region, monitor the IEEE 802.11 beacon signals withina wide evaluation region including the single channel, if the IEEE802.11 beacon signals are received within the wide evaluation region,reset the monitoring to the narrow evaluation region, and if the IEEE802.11 beacon signals are not received within the narrow evaluationregion after the IEEE 802.11 beacon signals were received within thewide evaluation region at least a predetermined number of times, thepredetermined number being greater than one, accept the wide evaluationregion.
 8. The apparatus of claim 7, wherein the at least one processoris further configured to cause the apparatus to establish communicationwith the wireless device.
 9. The apparatus of claim 7, wherein the atleast one processor is configured to cause the apparatus to widen themonitoring from the narrow evaluation region including the singlechannel to the wide evaluation region including the single channel whilemaintaining a same center frequency.
 10. The apparatus of claim 7,wherein the at least one processor is configured to cause the apparatusto reset the monitoring to the narrow evaluation region after apredetermined period of time.